Modelling phenolic and volatile composition to characterize the effects of pre-fermentative cold soaking in Tempranillo wines

Accepted Manuscript Modelling phenolic and volatile composition to characterize the effects of prefermentative cold soaking in Tempranillo wines Dr. José L. Aleixandre-Tudó, Inmaculada Álvarez, Victoria Lizama, Hélène Nieuwoudt, María J. García, José L. Aleixandre, Wessel J. du Toit PII:

S0023-6438(15)30251-6

DOI:

10.1016/j.lwt.2015.10.033

Reference:

YFSTL 5028

To appear in:

LWT - Food Science and Technology

Received Date: 13 July 2015 Revised Date:

17 September 2015

Accepted Date: 12 October 2015

Please cite this article as: Aleixandre-Tudó, J.L, Álvarez, I., Lizama, V., Nieuwoudt, H., García, M.J., Aleixandre, J.L., du Toit, W.J., Modelling phenolic and volatile composition to characterize the effects of pre-fermentative cold soaking in Tempranillo wines, LWT - Food Science and Technology (2015), doi: 10.1016/j.lwt.2015.10.033. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

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Modelling phenolic and volatile composition to characterize the effects of pre-fermentative cold soaking in Tempranillo wines

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José L. Aleixandre-Tudó,1,3,* Inmaculada Álvarez,3 Victoria Lizama,3 Hélène

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Nieuwoudt,2 María J. García,3 José L. Aleixandre3 and Wessel J. du Toit1,2

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(1) Department of Viticulture and Oenology and (2)Institute for Wine

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Biotechnology, Stellenbosch University, Private Bag X1, Matieland, 7602,

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South Africa.

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(3) Departamento de Tecnología de Alimentos, Universitat Politecnica de Valencia, Camino de Vera s/n, 46022, Valencia, Spain. *Corresponding author

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Dr. Jose Luis Aleixandre- Tudó

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Tel.: (+27) 21-808 9206

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Fax: (+27) 21-808 4781

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E-mail: [email protected]

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ACCEPTED MANUSCRIPT ABSTRACT

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The impact of pre-fermentative cold soak, alone or in combination with dry ice

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addition, on colour, phenolic and volatile composition of Tempranillo wines at 12

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months after bottling was studied. A control wine without cold soak was also evaluated.

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A sample set consisting of 66 wines was investigated. The results from ANOVA and

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PCA analysis showed significant treatment-related differences for a number of chemical

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measurements, as well as overlapping effects. Orthogonal projections to latent

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structures discriminant analysis (OPLS-DA) of the data showed that the dry ice addition

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treatment had a major effect on the anthocyanin fraction and on the levels of ethyl

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decanoate, 2-phenylethyl acetate and decanoic acid. In comparison, the cold soak

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treatment only had a slight effect on the bisulphite bleaching anthocyanins and volatile

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composition.

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Keywords: cold soak, dry ice, phenolics, volatiles and OPLS-DA

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1. INTRODUCTION

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Polyphenols and volatiles are essential for wine colour, mouth-feel and flavour.

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The relative proportions of anthocyanins and tannins can be adjusted during skin

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maceration to achieve a wine capable of undergoing good evolution during aging

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(Glories & Galvin, 1990). Therefore, when fruity and full bodied red wines are required,

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pre-fermentative cold maceration appears as an alternative for winemakers (Cai et al.,

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2014). However, the effects of pre-fermentative techniques are highly dependent on

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grape sanitary status and phenolic ripeness (Álvarez, Aleixandre, García, & Lizama,

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2006), as well as on the aromatic nature of the variety (Moreno-Pérez, Vila-López, &

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Fernández-Fernández, 2013).

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ACCEPTED MANUSCRIPT Skin polyphenols and volatile compounds are extracted throughout the pre-

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fermentative cold soak in the absence of ethanol (Gomez-Míguez, Gonzalez-Miret, &

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Heredia, 2007). Dry ice (solid carbon dioxide) addition appears as a common method to

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obtain the cold temperatures required for this technique (Heredia et al., 2010). After

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crushing and dry ice addition, grape skin cells are broken and disorganized through

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freezing, which facilitates aroma and phenolic extraction (Álvarez, Aleixandre, García,

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Lizama, & Aleixandre-Tudó, 2009).

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Contradictory results have been observed in the literature regarding the effect of

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pre-fermentative cold soak techniques on chemical wine composition. Several studies

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have shown that cold soak has either no effect, while a decrease in phenolic levels was

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also observed (Heatherbell, Dicey, Goldsworthy, & Vanhanen, 1997; Marais, 2003;

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Okubo, Goto-Yamamoto, & Okazaki, 2003: de Beer, Joubert, Marais, & Manley, 2006).

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Other authors noticed an increased phenolic content and higher sensory scores when

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wines were cold soaked before fermentation (Koyama, Goto-Yamamoto, & Hashizume,

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2007; Gil-Muñoz et al., 2009; Gordillo, López-Infante, Ramírez-Pérez, González-Miret,

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& Heredia, 2010: Heredia et al., 2010). During the cold soak step numerous reactions

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between grape phenolics also occur, which may influence wine sensory properties

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(Parenti, Spugnoli, Calamai, Ferrari, & Gori, 2004). Moreover, other compounds

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(proteins and polysaccharides) are also extracted, which may participate in condensation

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reactions (Gómez-Plaza, Gil-Muñoz, López-Roca, Martínez-Cutillas, & Fernández-

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Fernández, 2001).

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Pre-fermentative techniques have been used extensively in the production of

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white and rosé wines and have been recommended as a means for enhancing wine

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aroma (Sanchez-Palomo, Gonzalez-Viñas, Díaz-Maroto, Soriano-Perez, & Perez-Coello

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2007). Cold soak has also been tested in red winemaking (Sacchi, Bisson, & Adam, 3

ACCEPTED MANUSCRIPT 2005). However, little is known about its effect on the volatile composition. Moreno-

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Perez, Vila-López, and Fernández-Fernández (2013) cited differences between cold

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soak treated red wines and conventional winemaking after six months of bottling,

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although no differences between pre-treatments (cold soak, freezing grapes and dry ice

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addition) were observed. Moreover, in Monastrell wines increased volatile compound

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levels were reported for Monastrell wines produced by dry ice addition after 6 months

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of bottle storage (Álvarez, Aleixandre, García, & Lizama, 2006).

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Based on these contradictory reports, the aim of this work was thus to evaluate

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the impact of cold soak techniques on color, phenolic and volatile composition of red

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Tempranillo wines at 12 months of bottle storage. Tempranillo is one of the most

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widely planted grape cultivars in Spain and wines made from this cultivar are

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increasingly being accepted in new world wine producing countries such as Australia

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and the United States (Cynkar, Dambergs, Smith, & Cozzolino, 2010; USDA, 2014).

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2. MATERIALS AND METHODS

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2.1. Wine Samples. Tempranillo grapes from a commercial vineyard (Utiel-

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Requena, Valencia, Spain) were harvested in 2008. At harvest, the grapes had

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221.33±9.29 g/L of total sugar content, total acidity of 6.1±0.2 g/L as tartaric acid, pH

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of 3.34±0.12 and potential alcohol of 13.07±0.64% vol. (N=3). Wines were produced at

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an experimental wine production centre (Universitat Politècnica de València (UPV)). 40

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kg of grapes were destemmed, crushed, mixed and divided into closed 50 L stainless

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steel tanks. Potassium bisulphite was added at 100 mg/kg before fermentation.

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Treatments consisted of traditional vinification wines (T-V) without cold soak (control);

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cold soaked wines at 6 to 8ºC for four days (C-S); and dry ice addition (0 to 2ºC)

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followed by cold soak at 6 to 8ºC for four days (D-I). Twenty-two small scale

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ACCEPTED MANUSCRIPT vinifications were made for each treatment. After the cold soak period wines were left

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to warm up in the fermentation room and commercial yeasts were inoculated at 20 g/hL

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(Saccharomyces cerevisiae strain EP 841, Agrovin, Spain). The highest temperature

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during fermentation was 25ºC. Manual punching down was carried out twice a day. T-V

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wines were left on the skins for 15 days to ensure that sugar levels were lower than 2

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g/L. Following the same workflow, C-S and D-I wines were also left on the skins for 15

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days after the four days cold soak treatment. After fermentation wines were pressed and

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the first 5 L were mixed with 20 L free-run wine. Oenococcus oeni strain OE 104

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(Agrovin, Spain) lactic acid bacteria was inoculated and malolactic fermentation (MLF)

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was conducted at room temperature (~20 ºC). Potassium bisulphite was added at 50

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mg/L before bottling. Wines were stored at room temperature (15±2oC) and cork

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closures were used.

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2.2. Analytical methods. A UV-Visible JASCO V-530 spectrophotometer, and

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a JASCO MD-2010 Plus high-performance liquid chromatography instrument coupled

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with a diode array detector (DAD) (JASCO LC-Net II/ADC, Tokyo, Japan) were used

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for phenolic measurements. All the spectrophotometric measurements were performed

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in triplicate. Using the analytical methods described by Glories (1984) colour intensity,

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hue, gelatin (astringency) and EtOH (tannin-polysaccharide molecules) indexes were

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estimated. The Ribéreau-Gayon and Stonestreet (1965) method was used for the

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determination of bisulphite bleached anthocyanins. Catechins were quantified using the

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method reported by Sun, Ricardo Da Silva, and Spranger (1998). The modified version

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of the MCP tannin assay reported by Mercurio, Dambergs, Herderich, and Smith (2007)

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was used for tannin quantification. The method reported by Boulton (1996) was used to

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analyze the contribution of the copigmented, free and polymeric anthocyanins to the

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total wine colour. PVPP (anthocyanin-tannin complexes) and DMACH (tannin degree

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of polymerization) indexes were calculated according to Vivas and Glories (1995). The

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Folin-Ciocalteu index was determined using the method developed by Singleton and

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Rossi (1965). HPLC was used to quantify individual phenolic compounds using the method

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reported by Jensen, Blachez, Egebo and Meyer (2007). Gallic acid, (+)-catechin and (-)-

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epicatechin were quantified at 280 nm. Flavan-3-ols were defined as the sum of (+)-

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catechin and (-)-epicatechin. Hydroxycinnamic acids were quantified at 316 nm.

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Phenolic acids were calculated as the sum of gallic and hydroxycinnamic acids.

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Flavonols were quantified at 365 nm. Total anthocyanins were calculated as the sum of

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anthocyanidin-3-glucosides and acylated anthocyanins (derivated anthocyanins). Within

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each phenolic group, compounds were identified based on their intrinsic spectral

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features and retention times. Commercially available standards were used to build the

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calibration curves for phenolics quantifications: gallic acid (Fluka, Milwaukee, WI,

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USA), (+)-catechin (Fluka, Milwaukee, WI, USA) for flavan-3-ols, caffeic acid (Fluka,

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Milwaukee, WI, USA) for hydroxycinnamic acids, rutin (Sigma-Aldrich, St Louis, MO)

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for flavonols and malvidine-3-glucoside (Sigma-Aldrich, St Louis, MO) for

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anthocyanins. 20 µL of the wine sample were injected twice after centrifugation (5000

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rpm) and filtration (0.45 µm membrane Millipore filter). Separation was carried out on a

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Gemini NX (Phenomenex, Torrance, CA) 5 µm, 250 mm x 4.6 mm i.d. column at 40ºC.

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Acetonitrile and o-phosphoric acid were used as solvents. Solvents composition and the

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elution gradient were reported elsewhere (Jensen, Blachez, Egebo, & Meyer, 2007).

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An Agilent gas chromatograph (GC) (Agilent Technologies, Waldbronn,

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Germany) equipped with a split/splitless capillary injection port and flame ionization

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detector (FID) was used for the analysis of the wine aroma composition. Separations

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were performed on a ZB- WAX Plus column (50 m x 0.25 mm i.d., 0.25 µm film 6

ACCEPTED MANUSCRIPT thickness) from Phenomenex (Aschaffenburg, Germany). Duplicate injections were

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performed using the following conditions: injector temperature, 250°C; detector

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temperature, 300°C; carrier gas flow (N2), 1 mL/min. Injections were made in split

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mode (split ratio, 1/60; sample size, 1 µl). The oven temperature was maintained at

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40°C for 7 min, from 40 to 110°C at 4 °C/min, from 110 to 170°C at 10°C/min, and

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then held for 10 min. The comparison of retention times with those of standard

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compounds was used to identify volatile compounds. Preparation of the samples was

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carried out following the method proposed by Hernanz, Heredia, Beltran, and

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Recamales (1999). Twenty volatile compounds were quantified with 2-octanol as

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internal standard.

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2.3. Statistical analysis. Statgraphics Plus 5.1 software was used for the

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ANOVA treatment of the data. Principal component analysis (PCA) and orthogonal

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projections to latent structures discriminant analysis (OPLS-DA) (Trygg & Wold, 2002)

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was performed using SIMCA version 13.0.3 software (www.umetrics.com). Chemical

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measurements were Pareto (1/√Standard Deviation) scaled. The advantages of Pareto

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scaling have been defined as a means of reducing the impact of noise and artefacts in

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the models (Wiklund et al., 2008).

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3. RESULTS AND DISCUSION

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3.1. Effect of pre-fermentative maceration techniques on wine phenolic

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composition. ANOVA results showed no differences between the control and pre-

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fermentative treated wines in colour density and hue after 12 months of bottling (Table

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1). Bisulphite bleaching anthocyanins showed higher values in cold soaked (C-S) and

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dry ice added (D-I) wines. Higher levels of malvidine-3-monoglucoside, sum of

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anthocyanidins and total anthocyanins were found in D-I wines. These results are in

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ACCEPTED MANUSCRIPT accordance with those obtained by Álvarez, Aleixandre, García, & Lizama (2006) and

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Gil-Muñoz et al. (2009) which indicate an increase in the anthocyanin concentrations

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due to cold soak with dry ice addition. The higher anthocyanin derivates values

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observed might support the idea that dry ice addition is capable of increasing not only

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the free anthocyanin fraction. The extraction of other low molecular weight phenolics

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that could react with free anthocyanins might give rise to more complex anthocyanin

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moieties (Aleixandre-Tudó et al., 2013). Gil-Muñoz et al. (2009) also reported increased

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phenolic extraction and an improvement on the chromatic characteristics in cold soaked

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wines.

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Pre-fermentative cold soak techniques have been reported to influence the

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presence of phenolic compounds with high copigmentation potential (Álvarez,

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Aleixandre, García, Lizama, & Aleixandre-Tudó, 2009; Heredia et al., 2010). Despite

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the reported results no differences in the copigmentation fraction were observed.

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Copigmented anthocyanins account for almost half of the observed colour in young red

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wines and it is thought that anthocyanins may take part in future condensation reactions.

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Moreover, it is also believed that at early stages of fermentation the anthocyanin-

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copigment molecules can prevent anthocyanin oxidation, favouring further covalent

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tannin-anthocyanin interaction (Boulton, 2001).

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The colour resulting from the free non-copigmented anthocyanins and the

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flavan-3-ol concentration was also higher in D-I wines. Parenti, Spugnoli, Calamai,

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Ferrari, and Gori (2004) reported increased flavan-3-ol, tannin and anthocyanin

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concentrations in cold soaked wines after bottling, which led to more anthocyanin-

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tannin interactions. Contrarily to what was reported, anthocyanin-tannin interactions

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(PVPP index and % of colour due to polymeric anthocyanins) were not increased in this

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study at 12 months of bottling. 8

ACCEPTED MANUSCRIPT 3.2 Effect of pre-fermentative cold soak techniques on wine volatile

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composition. The ANOVA results showed that pre-fermentative cold soak techniques

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caused significant differences (Table 2) in fatty acids (octanoic and decanoic acid),

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ethyl esters (ethyl hexanoate and ethyl decanoate), an ester (2-Phenylethyl acetate), a

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volatile phenol (4-vinylphenol) and a lactone (γ-butyrolactone). The concentration of

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octanoic acid was lower in C-S and D-I wines, while the opposite was found for

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decanoic acid, although only significant for D-I wines. Moreover, no trends were

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observed in the esters and ethyl esters levels found for the different treatments. The

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levels of 4-vinylphenol were lower for D-I wines when compared to T-V and C-S

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treatments. Finally γ-butyrolactone levels seem to be diminished by cold soak

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treatments, with T-V wines having the highest levels of this compound. Moreno-Pérez,

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Vila-López, and Fernández-Fernández (2013) were not able to discriminate between the

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volatile composition of cold soaked Monastrell, Cabernet Sauvignon and Syrah cold

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soaked wines (freezing grapes, dry ice and cold soak) and concluded that these effects

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were variety dependent.

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The large within treatment variations (as indicated by high standard deviations),

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probably caused by the large number of small scale fermentations, could possibly

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explain why non-significant differences were observed for some compounds (Table 2).

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Contrarily to univariate techniques such as ANOVA that compare only one variable at

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the time, multivariate techniques include more than one statistical variable and include

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the effect of all variables on the responses of interest. PCA and OPLS-DA were thus

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performed to explore the factors that could contribute to the variation between

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treatments.

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3.3. Multivariate data analysis. In order to investigate the relationship between

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chemical composition and treatments in a more holistic approach, PCA was performed 9

ACCEPTED MANUSCRIPT on the 66 samples and 44 variables (24 phenolic measurements and 20 volatile

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compounds). The bi-plot (Figure 1 (a)) showed that the first two principal components

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captured 93.7 % of the explained variance (PC1 = 60.6 % and PC2 = 33.1 %) in the

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dataset. Although some differences were shown in the ANOVA, no clear trend based on

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treatments was observed in the PCA plot (i.e. no grouping of samples), thereby making

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it difficult to understand which chemical compounds were correlated to the applied pre-

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fermentative techniques.

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As has been reported by several authors, cold pre-fermentative techniques might

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initially increase anthocyanin and phenolic extraction (Gil-Muñoz et al., 2009),

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although the reactions that occur during storage could reduce or even negate this effect.

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In a study reported by Ortega-Heras, Pérez-Magariño, and González-Sanjosé (2012) the

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higher extraction of some phenolic compounds induced by cold soak was no longer

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evident at the end of bottle aging (12 months). Other authors reported that the effect

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might depend on the vintage, which could be related to the phenolic maturity of the

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grapes (Álvarez, Aleixandre, García, & Lizama, 2006, de Beer, Joubert, Marais, &

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Manley, 2006). The discrepancies in the abovementioned studies indicated that the

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effect could also depend on the variety used (Gil-Muñoz et al., 2009; Bussé-Valverde et

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al., 2010).

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With the aim of further investigating the differences between treatments, the

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OPLS-DA technique was applied to the data. OPLS-DA removes variability in X

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(chemical data) that is orthogonal to Y (treatments), by separating systematic variation

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into predictive components and orthogonal components (Lee, Hong, & Lee, 2009).

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Figure 1 (B) shows OPLS-DA bi-plot of pre-fermentative cold soaked (C-S and

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D-I) and control wines (T-V) using the complete set of 66 wines and 44 variables

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ACCEPTED MANUSCRIPT (chemical data). The model resulted in two predictive components and five orthogonal

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components, with cross-validated predictive ability Q2(Y) = 52.3 %, total explained

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variance R2(X) = 98.7 %, and variance related to treatment effect R2p(X) = 7 %.

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Compared to the results obtained with PCA, OPLS-DA exhibited an improved

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separation of cold soaked and control wines (Figure 1 (b)). C-S and D-I wines were

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mostly located towards the negative end of PC1, and T-V wines towards the positive

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end. Moreover, a differentiation between C-S and D-I wines was observed on PC2, with

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C-S wines located towards the positive end, and D-I towards the negative end.

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In order to further investigate the effect of cold soak treatments on the chemical

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composition of the wines, only the statistically significant compounds identified in the

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ANOVA were considered. In addition, pairwise comparisons of the chemical

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composition of T-V, C-S wines and D-I wines were performed. Figure 2 shows the

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cross-validated OPLS-DA scores plots (a.1, b.1 and c.1) and the S-plots (a.2, b.2 and

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c.2) that were constructed on the pair-wise comparisons. S-plots are scatter plots of the

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predictive values obtained by cross validation vs. the correlation vectors. The S-plot

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often takes an “S” shape if the X variables are scaled to Pareto variance. X variables

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located far out of the “S” wings combine high covariance and correlation and are

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therefore important contributors to the differences between treatments.

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The comparison of significant variables in T-V and C-S wines is shown in

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Figure 2(a.1 and a.2), and a clear separation between samples of the different treatments

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was not observed (Figure 2(a.1)). The volatile compounds ethyl decaoate (EDe), ethyl

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hexanoate (EHe) and octanoic acid (OcA) appeared located on the lower edge of the “S”

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wing and are therefore highly correlated with T-V wines. On the other hand, looking at

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the opposite side of the S-plot, the volatile compounds decanoic acid (DeA) and 2-

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phenylethyl acetate (2PA) together with the bisulphite bleaching anthocyanins (BBA) 11

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were important contributors to C-S wines (Figure 2(A.2)). Figure 2(b.1 and b.2) also show the cross-validated OPLS-DA scores plot and

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the S-plot for the pair T-V vs. D-I. A better separation between samples was clearly

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observed, which could be interpreted as bigger differences in chemical composition

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between wines, than those observed between C-S and T-V tretments (Figure 2(b.1)). For

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the D-I and T-V pair, the volatile compounds octanoic acid (OcA), ethyl hexanoate

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(EHe), γ-butirolactone (Btl) and 4-vinilphenol (4VP) appeared to be correlated with T-V

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wines, while ethyl decanoate (Ede), 2-phenylethyl acetate (2PA) and decanoic acid

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(DeA), together with the parameters related with the anthocyanin fraction (malvidine

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(Mal), anthocyanidins (Ant), anthocyanin derivates (ADe), total anthocyanins (TAn),

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bisulfite bleaching anthocyanins (BBA) and % free anthocyanins (%FA)) and the

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parameter flavan-3-ols (Fla) appeared highly related with dry D-I wines (Figure 2(b.2)).

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Finally, the direct comparison between pre-fermentative techniques (C-S vs. D-

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I) is shown in Figure 2(c.1 and c.2). A clear separation between treatments was also

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observed (Figure 2(c.1)). These results suggested that the dry ice addition treatment (D-I

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wines) had the biggest influence on the volatile and phenolic composition of

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Tempranillo wines after 12 months of bottle aging. C-S wines also differed from T-V

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wines, although the variation in phenolic and volatile composition was less pronounced.

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The volatile compounds ethyl decanoate (EDe), 2-phenylethyl acetate (2PA) and

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decanoic acid (DeA), together with some of the mentioned anthocyanin related

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parameters, were strongly correlated with the D-I wines. On the other hand, volatile

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compounds such as octanoic acid (OcA), ethyl hexanoate (EHe), γ-butirolactone (Btl)

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and 4-vinilphenol (4VP) were correlated with C-S wines (Figure 2(C.2)).

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3.4. OPLS-DA classification. Classification models were established using half

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ACCEPTED MANUSCRIPT of the samples (N=33) for the calibration set, while the other 33 samples were used to

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validate the models. The classification results are shown in Table 3. In order to

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investigate which group of chemical compounds had the biggest influence on the

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differences between cold soak treatments the parameters were grouped based on the

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corresponding phenolic family and also on their aromatic chemical families (esters,

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higher alcohols, volatile phenols, fatty acids and lactones). Therefore groups containing

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anthocyanin (BBA, Del, Cya, Pet, Peo, Mal, Ant, Ade, ToA, %CA, %FA, %PA, PVI),

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tannin (PVI, Cat, Fla, Tan, DMI, EtI, GeI), phenolic acids (PhA) and flavonol (Flo)

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related parameters were tested. Two additional groups, one including the total phenolics

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parameter (FoI) and another considering the two wine colour related parameters (CDe

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and Hue) were also performed. Two groups including all the phenolic measurement and

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all the volatile compounds were also considered. Finally the classification was again

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performed taking into account all the variables included in the study (phenolic +

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volatiles). This last model showed a validation accuracy of 87.88% in classifying the

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cold soak techniques, thus highlighting the impact that pre-fermentative cooling

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techniques have on wine chemical composition.

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Within phenolic compounds, anthocyanin related parameters were 60.61%

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accurately classified in validation showing the effect of these techniques on the

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anthocyanin fraction. Finally when all the phenolic measurements were included in the

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model 54.55 % of the samples were accurately classified.

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Regarding volatile compounds, the ester group appeared as the group of

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compounds with the better ability to classify samples, with 63.64% of validation

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accuracy. Otherwise other groups of volatile compounds showed lower accuracy in

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classifying Tempranillo wines (Table 3). An important increase in ester levels has also

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been observed in cold soaked and dry ice added pre-fermentative macerated wines 13

ACCEPTED MANUSCRIPT (Table 2). Compounds such as ethyl decanoate (soap, floral, grape, fruity, fatty, and

317

pleasant) and 2-phenylethyl acetate (rose, honey, tobacco, fruity, flowery, pleasant)

318

were identified as important contributors of D-I wines aroma. In addition, when the

319

volatile compounds were all included in the prediction model, 81,82% of the samples

320

were correctly classified.

321

CONCLUSIONS

322

Dry ice addition led to significant effects on anthocyanins and flaval-3-ols

323

levels. However an increased formation of tannins and polymeric pigments was not

324

observed. Dry ice also influenced volatile composition with increased levels of ethyl

325

decanoate, 2-phenylethyl acetate and decanoic acid. Pre-fermentative cold soak caused

326

minor changes in the anthocyanins and volatile fraction. An extended cold soak period

327

might cause larger effects, but in this case economic reasons need to be considered.

328

Moreover from the classification analysis cold soak treatments seem to strongly

329

influence the volatile composition, especially esters, together with the anthocyanin

330

fraction. Finally it is important to mention that these results should be confirmed with

331

further investigations which include at least three seasons due to our study only being

332

conducted on a single vintage.

334 335

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AKNOWLEDGMENTS

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The research reported here is a project financially supported by the Spanish

Government (AGL 2006-10723-C02-02) which the authors gratefully acknowledge.

336

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ACCEPTED MANUSCRIPT Table 1 Colour and phenolic profile of Tempranillo wines after 12 month of bottle aging. Mean ± standard deviation values of the phenolic measurement. p-value

12,71 ± 1.55

12,52 ± 0.88

12,21 ± 1.06

0,39

Hue

71,20 ± 2.63

69,93 ± 2.28

70,84 ± 2.28

0,20

Bisulfite bleaching ant. (mg/L) (3)

BBA

271,85 ± 27.83 a

297,59 ± 38.96 b

287,27 ± 30.64 b

0,04*

Delfinidin-3-glucoside (mg/L) (4)

Del

33,10 ± 2.84

32,21 ± 1.85

33,58 ± 1.73

0,19

Cya

2,17 ± 2.15

2,15 ± 0.25

Pet

30,67 ± 31.93

31,93 ± 1.90

Peonidin-3-glucoside (mg/L) (7)

Peo

5,13 ± 1.01

5,20 ± 0.87

Malvidin-3-glucoside (mg/L) (8)

Mal

255,42 ± 18.40 a

Anthocyanidins (mg/L) (9)

Ant

326,49 ± 24.64 a

Anthocyanin derivates (mg/L) (10)

ADe

46,84 ± 3.69 a

48,33 ± 7.28 a

53,34 ± 8.63 b

0,00*

Total anthocyanis (mg/L) (11)

ToA

373,33 ± 25.24 a

377,16 ± 34.48 a

407,78 ± 32.23 b

0,00*

% Copigmented anthocyanins (12)

%CA

10,48 ± 2.65

10,61 ± 2.39

10,48 ± 2.25

0,91

% Free anthocyanins (13)

%FA

39,49 ± 1.21 a

40,72 ± 2.91 ab

41,98 ± 2.76 b

0,04*

% Polimerized anthocyanins (14)

%PA

PVPP index (15)

PVI

Folin index (16)

FoI

Phenolic acids (mg/L) (17)

PhA

Flavonols (mg/L) (18)

Flo Cat Fla

Tannins (g/L) (21)

Tan DMI

0,65

0,08

5,49 ± 0.90

0,49

257,34 ± 26.61 a

280,43 ± 25.88 b

0,00*

328,83 ± 30.30 a

354,45 ± 29.36 b

0,00*

50,03 ± 7.62

48,67 ± 3.54

47,54 ± 4.70

0,77

32,02 ± 3.07

32,79 ± 2.90

33,92 ± 2.98

0,07

46,22 ± 2.23

45,65 ± 1.95

45,56 ± 1.95

0,50

146,74 ± 29.40

148,56 ± 26.35

137,98 ± 26.56

0,34

61,27 ± 20.59

57,19 ± 20.87

63,38 ± 19.34

0,59

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Catechin assay (mg/L) (19) Flavan-3-ols (mg/L) (20)

2,33 ± 0.03

32,61 ± 2.42

RI PT

Cyanidin-3-glucoside (mg/L) (5) Petunidin-3-glucoside (mg/L) (6)

SC

CDe

Ethanol index (23)

85,49 ± 17.59

84,93 ± 15.05

85,49 ± 13.88

0,99

65,45 ± 19.01 a

70,16 ± 20.00 ab

80,89 ± 18.34 b

0,03*

2,15 ± 0.25 b

2,01 ± 0.20 a

2,03 ± 0.23 a

0,03*

43,76 ± 3.21

44,82 ± 3.99

0,29

43,41 ± 4.23

EtI

21,75 ± 5.89

23,96 ± 4.39

22,78 ± 4.83

0,25

GeI

64,97 ± 5.96

65,45 ± 10.12

65,53 ± 8.65

0,96

EP

n: number of samples involved in the analysis from each treatment. T-V: traditional vinification; C-S: cold soak; D-I: dry ice.*Statistical analysis ANOVA at 95% confidence level with same letters indicating no significant difference for Tukey’s test

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D-I (n=22)

Hue (2)

Gelatin index (24)

4 5 6 7

C-S (n=22)

Color density (1)

DMACH index (22)

3

T-V (n=22)

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T-V (n=22)

C-S (n=22)

D-I (n=22)

p-value

PTb,b

IsA

449,55 ± 221,45

704,91 ± 349,04

675,18 ± 550,59

0,07

30(I)#

Ethyl hexanoate (26)

EHe

173,27 ± 125,21 b

105,48 ± 34,87 a

85,90 ± 19,71 a

0,00*

50(I)#

Ethyl lactate (27)

ELa

12797,10 ± 10021,19

23283,53 ± 19508,42

21629,45 ± 20015,09

0,10

14000(II)¥

Cis-3-hexen-1-ol (28)

C3H

26,30 ± 19,55

18,22 ± 9,84

21,14 ± 17,22

0,25

400(III)α

Ethyl 3-hydroxybutyrate (29)

EHb

21,21 ± 11,84

21,79 ± 9,90

22,33 ± 15,42

0,96

20000(III)ρ

Isobutyric acid (30)

IbA

2731,74 ± 1398,11

2998,24 ± 1646,48

3032,73 ± 2053,87

0,82

2300(IV)g

4-Vinylphenol (31)

4Vp

27,29 ± 22,48 b

26,58 ± 18,69 b

8,43 ± 9,04 a

0,00*

180(III)§

Butyric acid (32)

BtA

6,60 ± 4,54

7,45 ± 4,78

7,27 ± 5,65

0,84

173(III)α

Ethyl decanoate (33)

EDe

425,89 ± 228,45 b

190,63 ± 68,13 a

573,95 ± 119,04 c

0,00*

200(I)¥

γ-Butyrolactone (34)

Btl

40,58 ± 23,75 b

26,77 ± 10,83 a

23,77 ± 9,69 a

0,00*

35(III)ρ

Isopentanoic acid (35)

IpA

3,69 ± 1,63

3,86 ± 2,44

Diethyl succinate (36)

DeS

535,60 ± 317,26

614,19 ± 299,84

2-Phenylethyl acetate (37)

2PA

163,38 ± 74,92 a

213,14 ± 50,23 a

Hexanoic acid (38)

HeA

3121,63 ± 1459,38

3161,95 ± 1632,91

2-Methoxyphenol (39)

2MP

197,77 ± 68,82

2-Phenylethanol (40)

2Pe

4-Ethylguaiacol (41)

SC

RI PT

Isoamyl acetate (25)

4,03 ± 2,68

0,89

30(III)α

713,82 ± 170,98

0,10

200000(III)¥

306,31 ± 140,36 b

0,00*

250(IV)#

2717,16 ± 1619,91

0,59

420(V)g

249,24 ± 77,78

247,83 ± 111,20

0,09

9.5(III)α

40792,84 ± 30714,08

47685,85 ± 29690,71

50851.00 ± 30873,27

0,54

14000(IV)¥

4Eg

283,54 ± 97,22

238,30 ± 64,57

209,23 ± 150,89

0,09

33(IV)#

Octanoic acid (42)

OcA

576,25 ± 259,34 b

422,5 ± 233,28 a

350,92 ± 185,84 a

0,01*

500(III)α

4-Ethylphenol (43)

4Ep

51,40 ± 19,30

39,36 ± 15,64

43,57 ± 21,57

0,11

440(IV)§

Decanoic acid (44)

DeA

308,73 ± 104,77 a

340,20 ± 66,34 ab

408,89 ± 170,14 b

0,03*

1000(III)α

M AN U

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Table 2 Volatile composition of Tempranillo wines after 12 month of bottle aging. Mean ± standard deviation values (µg/L) of the quantified volatile compounds.

n: number of samples involved in the analysis from each treatment. T-V: traditional vinification; C-S: cold soak; D-I: dry ice. PT: perception threshold. *Statistical analysis ANOVA at 95% confidence level with same letters indicating no significant difference for Tukey’s test. a

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The reference from which the value was obtained is given in parentheses: I (Swiegers, Bartowsky, Henschke, & Pretorius, 2005); II (Li, Tao, Wang, & Zhang, 2008); III (Culleré, Escudero, Cacho, & Ferreira, 2004); IV (Francis & Newton, 2005); V (Ferreira, López, Cacho, 2000).

11 12 13 14 15

Symbols correspond to different matrices from which the PT was obtained: 10% ethanol/water solution; ¥12% ethanol/water solution; §12% ethanol/water solution with 8 g/L glycerol and different salts; ρ10% ethanol/water solution with 5 g/L of tartaric acid at pH 3.2; α11% ethanol/water solution with 7 g/L glycerol and 5 g/L tartaric acid; g10% ethanol/water solution with 7 g/L glycerol at pH 3.0.

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Table 3 Summary of orthogonal projection to latent structures discriminant analysis (OPLS-DA) classification results

Color Total phenolics Anthocyanins Tannins Phenolic acids Flavonols Phenolics Esters Higher alcohols Fatty acids Volatile phenols Lactones Volatile compounds Phenolics + Volatiles

1,2 16 3-15 15,19-24 17 18 1-24 25-27,29,33,36,37 28,40 30,32,35,38,42,44 31,39,41,43 34 25-44 1-44

RI PT

Parameters included*

SC

Model

Cold soak Calibration (%) Validation (%) N=33 N=33 27,27 39,39 39,39 39,39 60,61 63,64 39,39 45,45 33,33 36,36 27,27 48,48 54,55 69,70 63,64 84,85 42,42 42,42 42,42 45,45 48,48 66,67 42,42 45,45 81,82 100 87,88 100

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*Parameters included in each model, numbers correspond to Table 1 and 2. 33 random selected samples were included in the calibration set while the remaining 33 were used for model validation.

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a)

Figure 1 Principal component analysis bi-plot (PCA) (A) and orthogonal projections on latent structures discriminant analysis bi-plot (OPLS-DA) (B) of phenolic determinations and volatile compounds of wines elaborated with pre-fermentative cold maceration techniques. ♦T-V wines; ●C-S wines; ■D-I wines. Phenolic and volatile abbreviations correspond to Table 1 and 2

b)

b.1)

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Figure 2 OPLS-DA scores plots and S-Plots considering the significant phenolic and volatile parameters identified in the ANOVA of wines elaborated with pre-fermentative cold maceration techniques. Comparison among T-V and C-S wine (A.1 and A.2), T-V and D-I wines (B.1 and B.2) and C-S and D-I wines (C.1 and C.2). ♦T-V wines, ●C-S wines, ■D-I wines. Phenolic and volatile abbreviations correspond to Table 1 and 2.

ACCEPTED MANUSCRIPT HIGHLIGHTS The effect of two cold soak techniques was investigated against control wines. Tempranillo wines were analyzed after twelve months of bottle storage

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Dry ice addition caused an important effect on wine anthocyanins and volatiles Differences between cold soak techniques were also observed

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The length of cold soak vs dry ice addition needs to be considered